Heat-Shrinkable Anti-Fomitic Device Incorporating Anti-Microbial Metal

ABSTRACT

A heat-shrinkable anti-fomitic device incorporating anti-microbial metal wherein the device, in the form of a bag or tube, forms a cover for an object, preventing cross-infection by bacteria and other pathogens that may reside on the object. Anti-microbial metal ions from the cover further reduce future cross-infection from the object by killing pathogens. The anti-microbial, heat-shrinkable, anti-fomitic device can have a sterile interior that is sealed or stored flat during manufacture to maintain sterility. Therefore, no outer wrapping for the anti-fomitic device is required. The anti-fomitic device can be inverted when used to cover the object to present an outer surface that is initially sterile. A plurality of such devices can be heat shrunk to an object such that removal of the outer layer will further prevent cross contamination. Heat shrink film materials for the coverings/bags serve as a barrier to the transmission of pathogens and conform closely to the covered object.

CROSS-REFERENCE TO OTHER INVENTIONS

This application claims the benefit under 35 U.S.C. §119 of the filing date of Provisional Application No. 60/943,485 filed Jun. 12, 2007. The 60/943,485 application is incorporated by reference herein, in its entirety, for all purposes.

BACKGROUND AND SUMMARY

As disclosed in one of the present inventors' U.S. Pat. Nos. 6,468,611 and 6,649,236, the problems of cross-infection and the production of antibiotic-resistant mutations have been subjects for concern in hospital settings, as well as in household and other settings, such as the hospitality industry (hotels, motels, bed and breakfast businesses, hostels, etc.). These problems are particularly problematic for those with compromised immune systems or with special bacterial, viral, fungal, parasitic, or other susceptibilities. The latter category of special susceptibilities may also include persons with allergies, and persons who develop one or more of a range of contact dermatitises, to name but a few non-limiting examples.

One way that bacteria, viruses, fungi, and other pathogens are transmitted is by fomites, which are inanimate agents of such transmissions, including, for example, bedding, toilet seats, clothes, table tops and other fixed surfaces, surgical equipment, computer keyboards, etc. Thus, a fomite (also called a fomes) may absorb or otherwise harbor one or more strains of pathogenic bacteria, fungi, viruses, etc., and later transmit those pathogens, by contact, to a human.

A common fomite is bedding, where commonly employed materials, such as cotton, act as wicks to carry pathogens far from the initial contact point with human skin, particularly when moisture is present (sweat, semen, saliva, vaginal secretions, secretions from wounds and open pimples, spilled drinks, etc.). Thus, when sheets and pillow cases are changed, the deeper lying material (mattress, mattress cover, pillow) still harbors potential pathogens of the previous user(s). Furthermore, the next user, particularly when moisture is introduced onto the “scene,” can become infected by reverse wicking; i.e., moisture can draw deep lying pathogens back toward the surface of the bedding that is in contact with the user.

Another common fomite is the surfaces encountered in bathrooms. As has been well documented for decades, toilet seats, the faucet handles of wash basins, door handles, etc., and other surfaces in bathrooms are commonly contaminated with E. coli and other pathogens. As but one illustration of the problem, one need only recognize that a user of a toilet often will leave the toilet with substantial E. coli contamination of at least one hand. That individual may then, in turn, contaminate the knob/handle of the toilet stall, and then one or more faucet handles at a wash basin. Said individual then washes his hands, but touches the one or more faucet handles that he had just contaminated in the process of turning off the water flow, thereby re-contaminating his hand(s). Thus, whatever is subsequently touched by the E. coli-contaminated hand(s) of that individual will also become so contaminated.

As another example of cross-contamination in the bathroom setting, pathogens on toilet seats may be transmittable to the next user. One such example is the herpes viruses, which may be transmitted to a subsequent contactor, particularly if that individual has an open wound. Other pathogens may similarly be so transmitted, though some will require relatively immediate contact by the next person when the pathogen is not hardy outside a “biological” setting (i.e., a setting having the requisite moisture and/or temperature close to human interior body temperature).

Yet another setting that is ripe for cross-contamination is the kitchen. Not only is there the well documented potential problems with contamination sources such as chicken skin (Salmonella, etc.), raw beef (E. coli, etc.), and insects and other bugs and parts thereof (keeping in mind that the FDA allows such contamination to prescribed levels), but also E. coli contamination due to the use of toilets by the kitchen worker (or from contamination by a previous user of the toilet). In the same manner noted above in the context of bathrooms, cross-contamination of faucet handles of wash basins/sinks in kitchens is wide spread. The kitchen cross-contamination problem may also be extended to include problems from the use of cutting boards (problematic particularly with porous material like wood) and from inadequate cooking of contaminated food. In addition, inadequate cleaning of virtually all kitchen surfaces into which human skin comes into contact, directly or indirectly, further compounds the problem of cross-contamination; and this would include not only faucet handles, but also table, counter and other surfaces, as well as handles to ovens, refrigerators, microwave units, etc.

Still another fomite is computer devices where keyboards are used by multiple users in such settings as libraries, computer labs, retail stores and offices. In fact, the Centers for Disease Control traced one norovirus outbreak to computers in a school.

Cross-contamination may also occur during travel. On public transportation such as airplanes, travelers are often provided with complimentary travel pillows. These pillows may have been used by numerous other travelers. Despite changing the outer coverings (which may not occur between flights), these pillows may still harbor pathogens spread by previous users. Similarly, headrests, armrests and cushions of airplane seats may also bear pathogens left by previous users.

U.S. Pat. Nos. 6,468,611 and 6,649,236 to Haskin disclose anti-fomitic devices in the form of a bag or envelope which forms a cover for an object for preventing cross-infection by bacteria and other pathogens that may reside on the object being covered. A sterile inner surface is inverted to form a sterile outer surface. While forming an anti-fomitic barrier when in use, these devices do not prevent future cross-infection from the newly-formed sterile outer surface or from the covered object after removal of the bag or envelope.

The anti-microbial properties of silver (silver ions) have been known for many years. The ancient Romans wrote of the healing powers of silver for treating wounds. More recently, silver nitrate and silver sulphadiazine have been employed topically for the treatment of burns due to the anti-microbial properties of silver. Similarly, silver-coated fibers have been used in surgical, burn, and wound dressings, such as those produced under the Silverlon® brand by Argentum Medical, LLC of Willowbrook, Ill. and the SilverSeal® brand by Noble Biomaterials, Inc. of Scranton, Pa. As such, the anti-microbial properties of silver have, thus far, primarily been used for wound dressings and such. Other similar metals with known anti-microbial properties include copper and zinc.

While the present inventor's U.S. Pat. Nos. 6,468,611 and 6,649,236 to anti-fomitic devices provided a solution to some of the above-mentioned problems, a need still exists for better fitting and adaptability of such anti-fomitic devices to the objects they cover and a way to reduce pathogens on these objects.

In the realm of medical and dental devices that come in direct contact with healthcare workers and patients, as well as in the realm of items common to the household and to the hospitality industry, a need exists for disposable covers that have improved fit and which act in a manner to actively disinfect the items covered to prevent future cross infection. Such covers are sometimes referred to as “drapes.” The covers should be simple in construction, and capable of easy and inexpensive production. The covers should be disposable. The covers should not permit the passage of bacteria and other disease causing organisms (pathogens) to pass from one side to the other. For example, organisms on a medical device should not be able to come in contact with a patient or healthcare worker, and, likewise, organisms on or in a patient or healthcare worker should not be able to penetrate the covers and thereby contaminate medical devices protected by the covers. Furthermore, the covers should have sufficient anti-microbial properties to kill a substantial portion of bacteria, fungi, and viri existing on the surface of the object covered and on the outer surface of the cover.

With respect to bedding and other applications (e.g., covers for equipment, faucet handles and other handles, etc.), the covers similarly should not permit the passage of pathogens from one side of the covers to the other. The covers preferably employ silver or the like (e.g., copper, zinc, etc.) in a manner sufficient to impart anti-microbial properties and should also be non-reactive with typical human skin so as not to produce irritation or contact dermatitis. The covers should be capable of easy and quick application for covering the desired object. Finally, the covers should be easily sealable or attachable, where applicable.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a perspective view of a bag embodiment for covering an object.

FIGS. 2A and 2B illustrate an embodiment of an anti-microbial barrier before and after heat shrinking.

FIGS. 2C and 2D illustrate an embodiment of an anti-microbial barrier that incorporates a plurality of layers, and FIG. 2E illustrates an embedded strip for selective removal of these layers.

FIG. 3 illustrates a perspective view of an embodiment with an “end pocket” at each end of an antimicrobial sheet that covers the front surface of an object.

FIG. 4 illustrates a cross sectional view along line 4-4 of FIG. 3.

FIG. 5 illustrates a perspective view of an embodiment in which an anti-microbial sheet of heat-shrinkable cover material and adhesive attachment mechanism are used to cover just the front and back surfaces of an object.

FIG. 6 illustrates a variation on the FIG. 5 embodiment in which the front of the object and the ends of the back are covered, with adhesive contacts being effected by the cover ends directly onto the back of the object.

FIG. 7 illustrates a perspective view showing sealing by heat sealing.

FIG. 8 illustrates a perspective view of an empty anti-microbial heat shrink bag whose internal surfaces are sterile.

FIG. 9 illustrates a cross sectional view of the internally sterile bag of FIG. 8 folded back upon itself as an object is positioned therein by pressing against one end of the bag.

FIG. 10 illustrates the cross sectional view of FIG. 9 with an open end of the bag being advanced in a direction to unfold the bag, and to cover the uncovered end of the object positioned therein.

FIGS. 11A and 11B illustrate an embodiment that uses a tubular structure for the barrier.

FIGS. 12A-12C illustrate close-up, cross-sectional embodiments of a barrier of material.

DETAILED DESCRIPTION OF THE INVENTION

Disclosed embodiments relate generally to an anti-microbial cover or barrier formed of shrink film material to prevent cross-infection. In particular, embodiments relate to a range of anti-microbial anti-fomitic covers to both prevent cross-infection and disinfect surfaces, including such covers for pillows, mattresses, surgical and diagnostic equipment, toilet seats, table and chair seat surfaces, wash basin faucet handles and other handles, etc. through a combination of the barrier and incorporation of an anti-microbial metal.

The series of embodiments disclosed achieve a variety of results and applications. As used herein, the term anti-microbial refers to the properties of being anti-bacterial, anti-fungal, and anti-viral.

In the following detailed descriptions, a flat object to be covered will be designated generally as A, and the cover therefore will be designated generally as B. In general, however, object A need not be flat. A can be virtually any item or part thereof, particularly an item or part that may come into contact with human skin or clothing, or A may be a body part (for example, a part covered by a diaper).

The cover B may be made of any disposable heat-shrinkable film material that is suitable for contact with human skin, and that also serves as a barrier at least to bacteria and other pathogens of a similar size. Further, the barrier comprising disposable heat-shrinkable film material will prevent smaller pathogens (for example, viruses) from reaching a user.

An embodiment provides a disposable, sealable bag or envelope structure or sheet material that is coated or impregnated with an anti-microbial metal, such as silver, copper, zinc and compounds containing ions thereof. The sealable bag or envelope structure is formed of heat-shrinkable film material for encasing and closely conforming to an object in a way that prevents the spread of bacteria and other pathogens among multiple persons using the same object and which further acts to kill at bacteria, fungi, and viri that are on the object and/or come in contact with the sealable bag or envelope structure.

The anti-microbial compounds can include, but are not limited to: silver, copper or zinc deposited by chemical or physical vapor deposition onto one or both surfaces of the barrier material; a coating containing nanoparticles of silver, copper or zinc one or both surfaces of the barrier material; and various salts of silver, copper or zinc bound to one or both surfaces of the barrier material. Suitable compounds provide sufficient ions of silver, copper, or zinc to cause the anti-microbial effect. Silver-coated polymeric fibers, such as X-Static® fiber from Noble Biomaterials, can be embedded in the barrier material or adhered to the surface thereof. For paper barrier materials, a known silver-based anti-microbial compound is disclosed in U.S. Pat. No. 5,709,870. For polymer barriers, a known silver-based anti-microbial compound is disclosed in U.S. Pat. No. 6,716,895. Similarly, a coating containing anti-microbial silver nanoparticles is disclosed in U.S. Pat. No. 6,822,034. Embodiments discussed herein comprise antimicrobial metals in amounts necessary to have the desired anti-microbial effect.

The heat shrink film can be any conventional shrink film material that is sufficiently impervious to pathogens, that is suitable for contact with human skin, and that has sufficient strength for the application, including, but not limited to, PVC shrink films, polyolefin shrink films, polyester shrink films, and polyethylene shrink films. The material should also be a suitable carrier for the anti-microbial metal. Another embodiment employs heat-shrinkable film that is biodegradable.

The object to be covered by the bag or envelope structure can be virtually any medical, surgical or diagnostic equipment item or part thereof, particularly an item or part that may come into contact with human skin or clothing, such as, for example and not as a limitation, an X-ray cassette or other X-ray recording device, a surgical instrument or diagnostic instrument, a bedding, table or chair seat surface, a faucet handle or any other handle. In addition, the object to be covered by the bag or envelope structure may be any other object that may be covered and that may come into contact with human skin or clothing, whether in a medical setting or not, such as, for example and not as a limitation, a pillow, a travel pillow, a mattress or table or chair seat cover, a cushion, a headrest, an armrest, a toilet seat cover, or a faucet handle or other handle. The object to be covered may also be a body part (for example, a part covered by a diaper). Collectively, the group of objects which may be covered may be referred to as “enclosed object(s)”.

The enclosed objects may be found in various settings where multiple persons may come in contact with them. As an example, and not as a limitation, the enclosed objects may be in a home, in a school, in a hospital or medical clinic, in an office, in a hotel, or on a public transportation vehicle such as a bus, train or airplane.

Referring to FIG. 1, A is featured as an object to be covered with sides 10 and 11, and ends 12 and 13. The cover B of FIG. 1 has the form of a bag or envelope with front (not shown), back 31, sealed end edge 32, and opening 33. Object A is inserted into opening 33 until it is completely covered.

Further embodiments provide multiple, optional closure/sealing methods for a disposable bag or envelope structure that is coated or impregnated with an anti-microbial metal and formed of shrink film material for encasing and tightly conforming to an enclosed object, including but not limited to adhesive (including, for example, adhesive strips that are covered with a protective sheet when not in use), heat sealing, hook-and-loop structures (for example, Velcro®), zip-lock structures, and tucked flaps.

Referring again to FIG. 1, any of the above-listed closure mechanisms may be used to seal opening 33.

Referring to FIG. 7, heat sealable plastic cover/bag B (51) encloses object A, and end 51 is closed is by conventional heat sealing, for example with an impulse sealer or an electrically heated anvil 52, combined with companion anvil 53. In addition, with suitable plastic, the anti-microbial cover can be heat shrunk about the object by subjecting the cover to a short blast of hot air.

Another embodiment provides a disposable, sealable bag that is coated or impregnated with an anti-microbial metal and formed of shrink film material for encasing an enclosed object, where the edges of the bag incorporate pleats or slits to facilitate enclosing a range of objects therein. In addition, with suitable plastic, the cover can be heat shrunk about the enclosed object by subjecting the cover to a short blast of hot air.

Referring to FIG. 1, the bag or cover B can optionally include slits 34 and 35 at the opening. The slits may extend about ⅓ to ½ of the way down edges 36 and 37 of the bag. The purpose of slits 34 and 35 is to facilitate insertion of the object into the bag. Similarly, edges 36 and 37 of the cover B could optionally include pleats in place of slits 34 and 35 is to facilitate covering objects of greater depth.

In another embodiment, heat may be applied in a number of ways to shrink the anti-fomitic heat-shrinkable film cover so that the film cover more closely conforms to the shape of the enclosed object. For example, where the enclosed object is in a home or hotel setting, hand-held hair dryers are frequently available and may be used to apply hot air to heat shrink the cover described above.

FIGS. 2A and 2B illustrate the operation of the heat shrink film to conform to the shape of the object covered. In FIG. 2A, an object A is enclosed in a bag or barrier B. Upon the application of heat to the barrier material that is formed from heat-shrinkable film material, the barrier B shrinks to conform to the surface of object A, as illustrated in FIG. 2B.

Another embodiment provides a plurality of over-wrapped, disposable covers formed of anti-microbial heat shrink film material for covering and closely conforming to a surgical instrument or diagnostic instrument (i.e. a drape), table or chair seat surface, faucet handle or other handle, bedding, etc., where the outermost cover of the plurality of covers can be disposably removed between contact of different persons to prevent cross-contamination. The exterior of the inner layers can be sterilized so that removal of each outer layer provides a new, totally clean surface, and the anti-microbial metal ions assist in keeping the outer surface free from pathogens.

Referring to FIG. 2C, an embodiment illustrates a plurality of heat-shrink film barriers B with anti-microbial metal thereon fitted around an object A. While illustrated as having three layers, the invention is not so limited and requires only two or more layers. When an outer barrier B′ becomes contaminated by contact with pathogens or the like, the barrier B′ can be removed, as illustrated in FIG. 2D, and disposed of prior to contact with other people to prevent cross contamination. To assist in removal of the plurality of anti-microbial heat-shrink film barriers B, B′, each can include an embedded strip, as illustrated by an embodiment shown in FIG. 2E, with a pull handle to ease removal of the film barrier. Preferably, the outer surface of each inner barrier B is sterilized so that removal of the adjacent outer layer B′ of the barrier will present a sterilized surface. Further, the anti-microbial metal in the film barriers will reduce future cross contamination.

Another embodiment provides a disposable bag that is coated or impregnated with anti-microbial metal and formed of shrink film material for covering and tightly conforming to the front of an enclosed object by providing “end pockets” at each end of a flat sheet of shrink film material. Thus, the front surface of the enclosed object is covered, as well as the back surface at each end to the extent of the depth of the two “end pockets”. The bag may be further shrunk to fit the enclosed object by the application of heat.

Referring to FIGS. 3 and 4, cover B is shown to comprise end pockets 38 and 39 and an intermediate portion 40 that covers the front surface 14 of the object. This embodiment is used by inserting object end 13 into end pocket 39, and object end 12 into end pocket 38. Heat can then be applied to further fit the cover B to the object A. FIG. 4 represents the cross sectional view along line 4-4 of FIG. 3.

Another embodiment is a disposable flat sheet formed of heat-shrinkable film material with a fastening mechanism on one surface at each end, such as, but without limitation, adhesive, such that the object to be covered by the sheet (for example, a table or chair seat surface, etc.) is placed face down on the sheet (or vice versa) and the two ends are folded around the object such that the fastener ends of the sheet overlap and may be fastened securely to each other, thus enclosing the object snugly in the sheet. Heat may then be applied to the heat-shrinkable film material, so that the cover shrinks to conform further to the surface of the covered object.

Referring to FIG. 5, cover B is shown as a single sheet 41 having ends 50 and 51. The inside of end 50 is provided with a coating of pressure-sensitive adhesive 42. The outside of end 51 is also provided with pressure-sensitive adhesive 43. The length of sheet 41 is sufficient to permit mutual contact of the entire widths of adhesive strips 42 and 43 when the sheet is wrapped around the enclosed object A. Any of the other closure mechanisms enumerated above may also be used.

Another embodiment provides a disposable flat sheet formed of heat-shrinkable film material for covering the front of an enclosed object by merely folding ends over to attach by adhesive to the back of the object. Heat may then be applied to the heat-shrinkable film material, so that the cover shrinks to conform further to the surface of the enclosed object.

Referring to FIG. 6, cover B is shown as a single sheet of anti-microbial heat shrink film material 45 that is coated with pressure-sensitive adhesive 46 at both ends, including a protective strip 47 that is removed by peeling just prior to application. In use, enclosed object A is positioned face down on the cover, protective strips 47 are removed, and the ends are wrapped around to the back, where the pressure-sensitive adhesive strips 46 engage the back 17 and optionally also sides 10 and 11 of the object.

Yet another embodiment provides a disposable bag structure that is coated or impregnated with anti-microbial metal and formed of shrink film material for covering and closely conforming to a medical device, surgical instrument or diagnostic instrument, table or chair seat surface, faucet handle or other handle, bedding, etc., where the disposable bag structure is part of a continuous structure of end-to-end bags that may be stored in rolled form, and with perforations or other scoring between adjacent bags to facilitate their separation when ready for use.

A further embodiment provides a disposable, sealable bag that is coated or impregnated with anti-microbial metal and formed of shrink film material that, prior to use, is folded back upon itself such that, once the object to be covered is inserted into the bag (and thereby is partially covered to the depth of that portion of the bag), the folded-over section is pulled over the remaining portion of the object, and closure is effected. Hence, the previously internal, sterile, folded-over bag surfaces become the external surfaces against which the skin of a person comes in contact. Such back-folded heat-shrinkable bags are intended for a broad range of applications, and may be used, for example but not as a limitation, for coverage of any of the group of enclosed objects described above.

Referring to FIGS. 8, 9 and 10, which are related, it is shown how a cover surface that will contact a person can be kept sterile until shortly before use. A plastic bag B has ends 55 and 56, a front 59, and a rear 60. Either or both ends 55 and 56 are sealed in such a manner that, while air-tight, they can be readily opened. This can be achieved by tack sealing or incorporation of a tear strip for the opening of a conventional heat seal. The remaining edges are sealed in any conventional air-tight permanent manner. The bag is prepared under sterile conditions such that at least the interior is sterile at time of use. In addition, end-to-end such bags may be prepared and stored on rolls, with appropriate scoring or perforations between the bags.

Referring to FIGS. 8 and 9, object A is pressed against one end of bag B, for example end 56, and forced in such a manner that the bag doubles back on itself to the point that end 56 abuts against end 55, and edge 12 of the object is flush against end 56. This operation may be aided by a sleeve-like jig (not shown) that fits around the object. Thereafter, sealed end 55 is opened fully, and the bag is peeled back on itself, as is shown in FIG. 10. Thus, the previously sterile inside surfaces of the bag are now on the outside of the bag, ready for engagement with the skin of a patient and free of bacteria and pathogens that may lurk on the surfaces of the object. This latter embodiment thereby provides the advantage of a potentially totally clean and initially sterile outer covering.

The inside-out principle demonstrated in FIGS. 8-10 may be applied to any of the group of enclosed objects previously described.

One benefit of the inside-out principle of FIGS. 8-10 is that bacteria and other pathogens on the skin of a medical patient may thereby be eliminated from the cross-contamination cycle that otherwise would prevail in the clinical setting using conventional uncovered objects.

Another embodiment provides a disposable tube or sleeve structure formed of shrink film material that is coated or impregnated with anti-microbial metal for encasing and tightly conforming to an enclosed object. Heat may be applied to the heat-shrinkable film material, so that the cover shrinks to conform further to the surface of the enclosed object.

Referring to FIG. 11A, a generally tubular structure formed of anti-microbial heat-shrink film material that is open at both endsis illustrated by barrier B. The tubular barrier B can, like the bags, be produced singly or on rolls with perforations for separating adjacent sections. Also like the bags, the tubular barrier can have a sterilized interior and be inverted prior to covering an object A so as to present a sterile surface.

After an object A is inserted into the tubular barrier B, heat can be applied to conform the anti-microbial shrink film material to the surface of the object A, as illustrated in FIG. 11B. If the film shrinks sufficiently, it can shrink against itself to form a seal at each end of the tubular barrier B.

FIGS. 12A, 12B, and 12C disclose close-up cross-sectional views of typical embodiments of the barrier of the cover B. FIG. 12A illustrates an embodiment of a barrier material that comprises a polymeric layer 20 that serves as a barrier to pathogens that has anti-microbial compounds 22 of the present invention adhered to at least one surface thereof (and to both surfaces in the illustrated embodiment). While illustrated as layers, the adhered anti-microbial compounds 22 are not limited to uniform coatings, and may also include non-uniform dispersions of material. Anti-microbial silver, copper, or zinc may be deposited by conventional vapor deposition techniques so as to have an effective amount of anti-microbial activity.

FIG. 12B illustrates another embodiment of a barrier material in which a polymeric layer 20 that serves as a barrier to pathogens is impregnated with fibers 24 coated or formed with anti-microbial compounds of the present invention.

FIG. 12C illustrates an embodiment of a barrier material in which a polymeric layer 20 that serves as a barrier to pathogens has fibers 24 coated or formed with anti-microbial compounds of the present invention adhered to at least one surface thereof (and to both surfaces in the illustrated embodiment).

Though the anti-microbial, anti-fomitic covers formed of heat shrink film material of variously-disclosed embodiments are directed mainly to medical, surgical and diagnostic apparatuses and computer keyboards, they also apply to such areas as pillows and mattresses, travel pillows, faucet handles and other handles, table and chair seat surfaces, armrests, headrests, toilet seats, etc. so as to both prevent contact with existing pathogens and reduce future transmission of pathogens from the object. Further, by using the back-folded bag embodiment of the present invention, a pillow cover, for example, may be made that permits a patient to experience a totally clean surface on which to place his head or other body part, and the anti-microbial action of the bag further reduces pathogens on the pillow. Alternatively, one or more of the embodiments may be used to provide a clean pillow cover for a pillow received and used during an airline flight or hotel stay.

The various embodiments overcome limitations in the prior art by providing a cover that can conform very closely to the object being covered, yet be easily slipped over the object prior to application of heat to the heat shrink film material, while also reducing contact with future pathogens through the anti-microbial properties of the metal ions.

Although described herein with reference to particular embodiments, one of ordinary skill in the art will recognize that numerous additional embodiments are possible and that various modifications can be made without departing from the scope of the present invention, which is limited only by the claims below. For example, the above embodiments have emphasized use with rectangular objects, and in one embodiment use with pillows, mattress covers, table covers, etc. However, it is to be understood that the general concepts may be applied to a broad range of surgical or diagnostic equipment, as well as numerous domestic and household applications not specifically enumerated herein. Thus, it is intended that the specific embodiments presented herein are not limiting as to scope, but, rather, detail specific embodiments that may be generalized to a larger constellation of potential applications. Further, any reference to claim elements in the singular, for example, using the articles “a,” “an,” or “the” is not to be construed as limiting the element to the singular. 

1. A heat-shrinkable anti-fomitic device incorporating anti-microbial metal for covering an object, comprising: a barrier sized to cover a surface of an object, the barrier having an interior surface for facing the object and an exterior surface, the barrier comprising: a heat-shrink film material that is a barrier to pathogens; an anti-microbial compound, the anti-microbial compound containing metal ions selected from the group consisting of silver, copper, and zinc.
 2. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, where the heat-shrink film material is a plastic selected from the group consisting of polyvinyl chloride, homopolymers of polyvinyl chloride, copolymers of polyvinyl chloride, polyesters, polyethylenes, polypropylenes, and polyolefins.
 3. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, wherein the barrier comprises a bag; the bag comprising a closed end and a removably sealed open end.
 4. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 3, where the removably sealed open end further comprises a closure mechanism.
 5. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 4, where the closure is a mechanism selected from the group consisting of heat sealing, pressure-sensitive adhesive, zipper, zip-lock fastener, tucked flap, and hook-and-loop.
 6. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 5, where the pressure-sensitive adhesive is protected with a strip of a material until the pressure-sensitive adhesive is needed.
 7. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 6, where the protective strip is a material selected from the group consisting of paper and plastic.
 8. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 3, wherein the bag further comprises a sterile interior surface, wherein said bag is initially air-tight and when the removably sealed open end is opened, the bag is turned inside out to cover said object, resulting in the sterile interior being on the outside.
 9. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 3, wherein the bag is dimensioned so as to enable covering of said object where the object is a member selected from the group consisting of surgical devices, surgical instruments, diagnostic equipment, pillows, mattresses, faucet handles, toilet seats, table tops, armrests, headrests and chair seats.
 10. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 3, further comprising said bag and said removably sealed open end of said bag being dimensioned so as to enable covering of said object when said object comprises bedding.
 11. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 10, wherein said bedding is selected from the group consisting of pillows and mattresses.
 12. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 3, further comprising the bag and the removably sealed open end of said bag being dimensioned so as to cover a pillow.
 13. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 3, further comprising the bag and the removably sealed open end of said bag being dimensioned so as to cover a mattress.
 14. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, wherein the barrier is a tubular structure comprising a first open end and a second open end.
 15. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 14, wherein the tubular structure further comprises a sterile interior surface, wherein said tubular structure is turned inside out to cover the object, resulting in the sterile interior being on the outside.
 16. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 14, further comprising the tubular structure being dimensioned so as to enable covering of said object where the object is selected from the group consisting of surgical devices, surgical instruments, diagnostic equipment, pillows, mattresses, faucet handles, toilet seats, table tops, and chair seats.
 17. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 14, further comprising the tubular structure and at least one open end of the tubular structure being dimensioned so as to cover an object selected from the group consisting of mattresses and pillows.
 18. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, further comprising a plurality of barriers of heat-shrink film.
 19. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 18, wherein the outer surface of each of the plurality of barriers is sterilized.
 20. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 18, wherein each of the plurality of barriers comprises an embedded pull strip to aid in removal of the shrink film from an object.
 21. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, wherein the anti-microbial compound is impregnated in the barrier.
 22. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, wherein the anti-microbial compound is coated on at least one of the interior surface and exterior surface of the barrier.
 23. The heat-shrinkable anti-fomitic device incorporating anti-microbial metal according to claim 1, wherein the barrier comprises a sheet of heat-shrink film material sized to wrap around an object.
 24. The heat-shrinkable anti-fomitic device according to claim 23, wherein the sheet of heat-shrink film material shrinks to conform further to the object when heat is applied. 